Part 19: Graviton Coherence
Field-Based Phase Transitions and the Collapse of Coherence
Graviton Pressure Theory (GPT) offers a unified causal framework for phase transitions, revealing them as coherence-dependent field responses rather than purely thermodynamic outcomes. Departing from classical thermodynamic and electromagnetic interpretations, GPT posits that all phase changes—including melting, magnetism loss, and fluid behavior—arise from the coherence dynamics of graviton pressure corridors within material structures. Solidity, magnetism, and fluidity are reframed as coherence states of internal graviton flow. Thermal energy acts not as an energizer but as a decoherence catalyst—disrupting the directional integrity of the field.
The document introduces precise definitions of melting points and Curie temperatures as coherence collapse thresholds, formalizes anisotropic phase transitions as directional corridor failure, and reframes liquids, gases, and plasmas as gradations of graviton alignment integrity. Key metrics such as internal pressure gradients, coherence indices, and field-sensitive viscosity are proposed for experimental validation. A gravimetric micro-shift experiment is outlined to detect coherence collapse at the melting point of iron, offering a predictive test for GPT. This work extends the gravitational ontology of matter, positioning all classical phase behaviors as field-interaction events, governed not by energy surplus but by structural alignment with self-repulsive, directional graviton flow. In doing so, it dissolves the boundary between thermodynamics, material science, and gravitational field theory—revealing each phase transition as a coherence memory collapse within a graviton-stabilized structure.
In classical physics, phase transitions such as melting, boiling, or the loss of magnetism are typically interpreted through thermal agitation or electromagnetic domain theory. These phenomena are often attributed to increased energy disrupting atomic bonds, overcoming structural thresholds, or altering spin alignments. While descriptively effective, these interpretations remain incomplete, lacking a unified causal mechanism. Graviton Pressure Theory (GPT) reframes these phase transitions as manifestations of graviton coherence dynamics. Rather than isolated thermodynamic or electromagnetic shifts, transitions are seen as coherence modulations in graviton-stabilized field structures. Solidity, fluidity, and magnetism are therefore treated not as static states of matter, but as outcomes of graviton corridor stability and coherence density.
In GPT, all matter is immersed in and stabilized by directional graviton pressure fields. These fields are composed of anisotropic, self-repulsive streams of gravitons that exert external pressure and induce alignment within structured matter. When atomic or subatomic arrangements align phase-coherently with graviton flow, stable material states such as solidity and magnetism emerge. As coherence decreases, matter transitions to less structured phases, driven by decoherence mechanisms such as thermal agitation. GPT defines temperature not as a fundamental cause, but as an agent of decoherence—a measure of disruption in the timing and phase alignment necessary to maintain graviton corridor integrity. From this view, structural phase change is a field-level event: a loss or gain of coherence with the directional graviton lattice.
The objective of this work is to unify electromagnetic, thermodynamic, and solid-state behavior under the framework of graviton coherence. Solidity, melting, magnetism, and fluidity are reinterpreted as coherence thresholds within the graviton field, extending prior analyses introduced in Magnetism as Gravimetric Resonance and positioning graviton coherence as a central regulator of material behavior.